# What is the best algorithm to find a determinant of a matrix?

Can anyone tell me which is the best algorithm to find the value of determinant of a matrix of size `N x N`?

• Do we know more about the matrix other than the size. Is it sparse?
– wcm
Mar 12 '10 at 19:15
• Despite the tagging the answers to stackoverflow.com/questions/1886280/… are language agnostic, so I propose that this is a duplicate. Mar 12 '10 at 19:42
• Matrix algorithms are sufficiently complex so that you ought not implement them yourself; use a well-established library like LAPACK. The people who write the library will already have chosen the best implementation for determinant (probably LU decomposition for a dense matrix). Mar 12 '10 at 22:35
• What algorithm does numpy use? Sep 23 '13 at 12:26

Here is an extensive discussion.

There are a lot of algorithms.

A simple one is to take the `LU` decomposition. Then, since

`````` det M = det LU = det L * det U
``````

and both `L` and `U` are triangular, the determinant is a product of the diagonal elements of `L` and `U`. That is `O(n^3)`. There exist more efficient algorithms.

# Row Reduction

The simplest way (and not a bad way, really) to find the determinant of an nxn matrix is by row reduction. By keeping in mind a few simple rules about determinants, we can solve in the form:

det(A) = α * det(R), where R is the row echelon form of the original matrix A, and α is some coefficient.

Finding the determinant of a matrix in row echelon form is really easy; you just find the product of the diagonal. Solving the determinant of the original matrix A then just boils down to calculating α as you find the row echelon form R.

## What You Need to Know

### What is row echelon form?

See this [link](http://stattrek.com/matrix-algebra/echelon-form.aspx) for a simple definition
**Note:** Not all definitions require 1s for the leading entries, and it is unnecessary for this algorithm.

### You Can Find R Using Elementary Row Operations

Swapping rows, adding multiples of another row, etc.

### You Derive α from Properties of Row Operations for Determinants

1. If B is a matrix obtained by multiplying a row of A by some non-zero constant ß, then

det(B) = ß * det(A)

• In other words, you can essentially 'factor out' a constant from a row by just pulling it out front of the determinant.
2. If B is a matrix obtained by swapping two rows of A, then

det(B) = -det(A)

• If you swap rows, flip the sign.
3. If B is a matrix obtained by adding a multiple of one row to another row in A, then

det(B) = det(A)

• The determinant doesn't change.

Note that you can find the determinant, in most cases, with only Rule 3 (when the diagonal of A has no zeros, I believe), and in all cases with only Rules 2 and 3. Rule 1 is helpful for humans doing math on paper, trying to avoid fractions.

## Example

(I do unnecessary steps to demonstrate each rule more clearly)

```  | 2  3  3  1 |
A=| 0  4  3 -3 |
| 2 -1 -1 -3 |
| 0 -4 -3  2 |
R2  R3, -α -> α (Rule 2)
| 2  3  3  1 |
-| 2 -1 -1 -3 |
| 0  4  3 -3 |
| 0 -4 -3  2 |
R2 - R1 -> R2 (Rule 3)
| 2  3  3  1 |
-| 0 -4 -4 -4 |
| 0  4  3 -3 |
| 0 -4 -3  2 |
R2/(-4) -> R2, -4α -> α (Rule 1)
| 2  3  3  1 |
4| 0  1  1  1 |
| 0  4  3 -3 |
| 0 -4 -3  2 |
R3 - 4R2 -> R3, R4 + 4R2 -> R4 (Rule 3, applied twice)
| 2  3  3  1 |
4| 0  1  1  1 |
| 0  0 -1 -7 |
| 0  0  1  6 |
R4 + R3 -> R3
| 2  3  3  1 |
4| 0  1  1  1 | = 4 ( 2 * 1 * -1 * -1 ) = 8
| 0  0 -1 -7 |
| 0  0  0 -1 |
```
``````def echelon_form(A, size):
for i in range(size - 1):
for j in range(size - 1, i, -1):
if A[j][i] == 0:
continue
else:
try:
req_ratio = A[j][i] / A[j - 1][i]
# A[j] = A[j] - req_ratio*A[j-1]
except ZeroDivisionError:
# A[j], A[j-1] = A[j-1], A[j]
for x in range(size):
temp = A[j][x]
A[j][x] = A[j-1][x]
A[j-1][x] = temp
continue
for k in range(size):
A[j][k] = A[j][k] - req_ratio * A[j - 1][k]
return A
``````

If you did an initial research, you've probably found that with N>=4, calculation of a matrix determinant becomes quite complex. Regarding algorithms, I would point you to Wikipedia article on Matrix determinants, specifically the "Algorithmic Implementation" section.

From my own experience, you can easily find a LU or QR decomposition algorithm in existing matrix libraries such as Alglib. The algorithm itself is not quite simple though.

I am not too familiar with LU factorization, but I know that in order to get either L or U, you need to make the initial matrix triangular (either upper triangular for U or lower triangular for L). However, once you get the matrix in triangular form for some nxn matrix A and assuming the only operation your code uses is Rb - k*Ra, you can just solve det(A) = Π T(i,i) from i=0 to n (i.e. det(A) = T(0,0) x T(1,1) x ... x T(n,n)) for the triangular matrix T. Check this link to see what I'm talking about. http://matrix.reshish.com/determinant.php